JP5440372B2 - Management device, management program, and communication system - Google Patents

Description

  The present invention relates to a management device, a management program, and a communication system.

  Boundary routers such as ASBR (Autonomous System Boundary Router) are installed between networks with different routing protocols, and notify route information in one network to the other network. In this way, the border router notifies the route information to each network, so that data communication can be performed mutually even between networks having different routing protocols.

  FIG. 8 is a diagram showing a conventional system configuration having a border router. As shown in FIG. 8, in this system, border routers 1 and 2 are arranged between networks 10 and 20 having different routing protocols. The border routers 1 and 2 transmit the route information received from the network 10 to the network 20. The border routers 1 and 2 transmit route information received from the network 20 to the network 10.

  The network 10 performs data communication based on an OSPF (Open Shortest Path First) routing protocol. The network 10 includes routers 11 to 13. The routers 11 to 13 determine an optimum route based on route information transmitted from the network 20 and perform data communication with the network 20.

  The network 20 performs data communication based on a routing protocol other than OSPF. The network 20 includes routers 21 to 23. The routers 21 to 23 determine an optimum route based on route information transmitted from the network 10 and perform data communication with the network 10. The router 21 is connected to the network 21a, and the router 22 is connected to the network 22b.

JP 2003-78558 A JP 2005-151027 A

  However, when a plurality of border routers are arranged between the networks, the same route information may loop through the networks 10 and 20, and there is a problem that traffic in the network increases.

  Here, as an example, the problem of the prior art will be described using a case where the router 21 notifies the network 10 of route information. The route information transmitted from the router 21 reaches the border router 1 and the border router 2.

  First, an example in which route information that reaches the border router 1 from the router 21 loops is shown. The border router 1 has a function of transmitting data received from one network to the other network. For this reason, the border router 1 transmits route information to the network 10, and this route information reaches the routers 11 to 13 and the border router 2. Since the border router 2 has the same function as that of the border router 1, the route information received from the border router 1 is transmitted to the router 23 as data transmitted from the network 10. Since this route information is originally route information of the network 20, the router 23 transmits the route information to the border router 1. Since such processing is performed by the border routers 1 and 2 and the router 23, a loop of route information occurs.

  Next, an example in which the route information that reaches the border router 2 from the router 21 loops is shown. The border router 2 transmits route information to the network 10, and this route information reaches the routers 11 to 13 and the border router 1. The border router 1 sends the route information received from the border router 2 to the router 23 as data sent from the network 10. Since this route information is originally route information of the network 20, the router 23 transmits the route information to the border router 2. Since such processing is performed by the border routers 1 and 2 and the router 23, a loop of route information occurs.

  It is conceivable to perform filtering settings on the border routers 1 and 2 so that the route information does not loop. However, this filtering setting is complicated, and places a burden on the border router administrator.

  The disclosed technology has been made in view of the above, and an object thereof is to provide a management device, a management program, and a communication system that can prevent the same route information from looping.

  The management device disclosed in the present application uniquely identifies router identification information for uniquely identifying a border router from a plurality of border routers connected between a plurality of networks having different routing protocols and a network to which data is transmitted and received. A receiving unit that receives path information including network identification information to be identified and a cost for transmitting / receiving data to / from the network, and a set of the network identification information and the cost of each path information are respectively compared. A determination unit that determines a border router of router identification information corresponding to a minimum cost among costs corresponding to the same network identification information, and transmission of the route information is permitted based on a determination result of the determination unit It is a requirement that a notification unit for notifying each border router of information on whether or not is provided.

  According to the management device disclosed in the present application, it is possible to prevent the same route information from being looped.

FIG. 1 is a diagram illustrating the configuration of the management apparatus according to the first embodiment. FIG. 2 is a diagram illustrating the configuration of the system according to the second embodiment. FIG. 3 is a diagram illustrating an example of a data structure of route information. FIG. 4 is a diagram illustrating the configuration of the management apparatus according to the second embodiment. FIG. 5 is a diagram illustrating an example of the data structure of the ASBR management table. FIG. 6 is a flowchart of the process procedure of the system according to the second embodiment. FIG. 7 is a diagram illustrating a hardware configuration of a computer constituting the management apparatus according to the embodiment. FIG. 8 is a diagram showing a conventional system configuration having a border router.

  Hereinafter, embodiments of a management device, a management program, and a communication system disclosed in the present application will be described in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

  FIG. 1 is a diagram illustrating the configuration of the management apparatus according to the first embodiment. As illustrated in FIG. 1, the management device 50 includes a reception unit 51, a determination unit 52, and a notification unit 53. The management device 50 is connected to a plurality of border routers connected between a plurality of networks having different routing protocols.

  The receiving unit 51 receives, from the border router, router identification information that uniquely identifies this border router, network identification information that uniquely identifies a network that is a data transmission / reception destination, and data that is transmitted / received to / from this network. The route information including the cost is received.

  The determination unit 52 compares the set of network identification information and cost of each route information, and among the costs corresponding to the same network identification information, the router identification information corresponding to the set of the minimum cost and the network identification information Determine the border router. Based on the determination result of the determination unit 52, the notification unit 53 notifies each border router of information on whether or not to permit transmission of route information.

  Based on the path information received from each border router, the management device 50 determines the border router that minimizes the cost when sending / receiving data to / from the data transmission / reception destination network. Then, the management device notifies each border router of information on whether or not to permit transmission of route information based on the determination result. As a result, since the border router that is permitted to transmit the route information transmits the route information, it is possible to prevent the same route information from looping through each network.

  A configuration of the system according to the second embodiment will be described. FIG. 2 is a diagram illustrating the configuration of the system according to the second embodiment. As shown in FIG. 2, in this system, border routers 60a and 60b are arranged between networks 70 and 80 having different routing protocols.

  The border router 60 a transmits the route information received from the network 80 to the management device 100 of the network 70. The border router 60 a does not transmit the route information to the routers 71 and 72 when receiving information indicating that transmission of the route information is not permitted from the management device 100 after transmitting the route information to the management device 100. On the other hand, if the border router 60a does not receive information indicating that transmission of route information is not permitted from the management device 100 within a predetermined time after transmitting the route information to the management device 100, the border router 60a displays the route information. The data is transmitted to the routers 71 and 72.

  The border router 60 b transmits the route information received from the network 80 to the management device 100 of the network 70. The border router 60b does not transmit the route information to the routers 71 and 72 when receiving information indicating that transmission of the route information is not permitted from the management device 100 after transmitting the route information to the management device 100. On the other hand, if the border router 60b does not receive information indicating that transmission of route information is not permitted from the management device 100 within a predetermined time after transmitting the route information to the management device 100, the border router 60b displays the route information. The data is transmitted to the routers 71 and 72.

  The network 70 performs data communication based on an OSPF (Open Shortest Path First) routing protocol. The network 70 includes routers 71 and 72 and a management device 100. The routers 71 and 72 determine an optimum route based on route information transmitted from the network 80 and perform data communication with the network 80.

  Based on the path information received from the border routers 60a and 60b, the management apparatus 100 determines the border router that minimizes the cost when sending and receiving data to and from the network that is the destination of data transmission and reception. Based on the determination result, the management apparatus 100 transmits information indicating that transmission of route information is not permitted to the border router 60a or the border router 60b.

  The network 80 performs data communication based on a routing protocol other than OSPF. The network 80 includes routers 81 to 83. The router 81 is connected to the network 81a and transmits route information of the network 81a to the border routers 60a and 60b. The router 81 may be connected to the network 82a. When the router 81 is connected to the network 82a, the route information of the network 82a is transmitted to the border routers 60a and 60b.

  The router 82 is connected to the network 82a and transmits route information of the network 82a to the border routers 60a and 60b. The router 82 may be connected to the network 81a. When connected to the network 81a, the router 82 transmits the route information of the network 81a to the border routers 60a and 60b. The router 83 relays data communication between the routers 81 and 82 and the border routers 60a and 60b.

  Here, the route information transmitted from the routers 81 and 82 to the border routers 60a and 60b includes information in which the network address is associated with the cost. Further, the route information transmitted from the border routers 60a and 60b to the management apparatus 100 includes border router identification information for identifying the border router, information in which the network address is associated with the cost.

  An example of a data structure of route information transmitted from the border routers 60a and 60b to the management apparatus 100 will be described. FIG. 3 is a diagram illustrating an example of a data structure of route information. As shown in FIG. 3, this route information stores boundary router identification information, a network address, and a cost in association with each other.

  Among these, the border router identification information is information that uniquely identifies the border router. For example, the border router identification information “R1001” corresponds to the border router 60a. The border router identification information “R1002” corresponds to the border router 60b.

  The network address corresponds to the IP (Internet Protocol) address of the network. For example, the network address “10.0.0.10” corresponds to the IP address of the network 81a. The network address “10.0.0.20” corresponds to the IP address of the network 82a.

  The cost is a value specified by a communication band from the data transmission source to the transmission destination, the number of hops, and the like. The cost decreases as the communication band increases. The cost increases as the number of hops increases. When the route information is transmitted, the routers 81 to 83 prepare a cost corresponding to the network in advance and register the prepared cost in the route information. The routers 81 to 83 may adjust the cost according to a change in communication band, a change in the number of hops, and the like.

  Next, the configuration of the management apparatus 100 shown in FIG. 2 will be described. FIG. 4 is a diagram illustrating the configuration of the management apparatus according to the second embodiment. As illustrated in FIG. 4, the management apparatus 100 includes a communication control unit 110, a route information registration unit 120, a storage unit 130, a determination unit 140, and a notification unit 150.

  The communication control unit 110 outputs the route information to the route information registration unit 120 when the route information is received from the border routers 60a and 60b. Further, the communication control unit 110 transmits the data output from the notification unit 150 to the border router 60a or the border router 60b. The data output from the notification unit 150 includes information indicating that transmission of route information is not permitted, as will be described later.

  The route information registration unit 120 is a processing unit that acquires route information from the communication control unit 110 and registers the route information in the ASBR management table 130 a of the storage unit 130. When the route information of the same set as the combination of the boundary router identification information and the network address of the route information is not registered in the ASBR management table 130a, the route information registration unit 120 displays the obtained route information in the ASBR management table. Newly registered in 130a. On the other hand, the route information registration unit 120, when the route information of the same set as the set of the boundary router identification information and the network address of the route information is registered in the ASBR management table 130a, Overwrite the corresponding information with information.

  The storage unit 130 is a storage unit that stores the ASBR management table 130a. The ASBR management table 130a is a table that stores route information transmitted from the border routers 60a and 60b. FIG. 5 is a diagram illustrating an example of the data structure of the ASBR management table. As shown in FIG. 5, the ASBR management table 130a stores boundary router identification information, a network address, a cost, and a priority flag in association with each other. Among these, the explanation about the border router identification information, the network address, and the cost is the same as the explanation about the border router identification information, the network address, and the cost shown in FIG.

  The priority flag is information for identifying a border router that permits transmission of route information. When the priority flag is “1”, transmission of route information is permitted. When the priority flag is “0”, it indicates that transmission of route information is not permitted.

  The priority flag is set for each different network address. First, the priority flag for the network address “10.0.0.10” in FIG. 5 will be described. The priority flag is “1” for the border router identification information “R1001” and “0” for the border router identification information “R1002”. This indicates that transmission of route information including the network address “10.0.0.10” is permitted to the border router 60a and not permitted to the border router 60b.

  Next, the priority flag for the network address “10.0.020” in FIG. 5 will be described. The priority flag is “1” for the border router identification information “R1002” and “0” for the border router identification information “R1001”. This indicates that transmission of route information including the network address “10.0.0.20” is permitted to the border router 60b and not permitted to the border router 60a. The value of the priority flag is set by the determination unit 140 described later.

  The determination unit 140 is a processing unit that determines a boundary router that permits transmission of route information and a boundary router that does not permit transmission of route information based on the ASBR management table 130 a, and outputs the determination result to the notification unit 150. Hereinafter, the processing of the determination unit 140 will be specifically described.

  The determination unit 140 refers to the ASBR management table 130a and extracts costs corresponding to the same network address. The determination unit 140 compares the extracted costs, sets the priority flag of the lowest cost to “1”, and sets the priority flags of other costs to “0”.

  As shown in FIG. 5, the costs of the network address “10.0.0.10” are “20” and “30”. Among the costs “20” and “30”, the minimum cost is “20”. Therefore, the determination unit 140 sets the priority flag for the set of the network address “10.0.0.10” and the cost “20” to “1”. Further, the determination unit 140 sets the priority flag for the set of the network address “10.0.0.10” and the cost “30” to “0”. In this case, the border router identification information of the border router that is permitted to transmit route information including the network address “10.0.0.10” is “R1001”. On the other hand, the border router identification information of the border router that is not permitted to transmit route information including the network address “10.0.0.10” is “R1002”.

  Further, as shown in FIG. 5, the costs of the network address “10.0.020” are “20” and “30”, respectively. Among the costs “20” and “30”, the minimum cost is “20”. Therefore, the determination unit 140 sets the priority flag for the set of the network address “10.0.020” and the cost “20” to “1”. Further, the determination unit 140 sets the priority flag for the set of the network address “10.0.020” and the cost “30” to “0”. In this case, the border router identification information of the border router permitted to transmit the route information including the network address “10.0.020” is “R1002”. On the other hand, the border router identification information of the border router that is not permitted to transmit the route information including the network address “10.0.020” is “R1001”.

  The determination unit 140 sets the priority flag in the ASBR management table 130a, and then outputs the information in the ASBR management table 130a to the notification unit 150. The determination unit 140 may reset the priority flag every time the ASBR management table 130a is updated, or may reset the priority flag every predetermined time interval.

  Based on the ASBR management table 130a notified from the determination unit 140, the notification unit 150 identifies a border router that does not permit transmission of route information, and transmits information indicating that transmission of route information is not permitted. Information indicating that the notification unit 150 does not permit transmission of route information transmitted to the border router is referred to as transmission control information. This transmission control information includes information indicating that transmission of route information is not permitted and a network address.

  In the example illustrated in FIG. 5, the notification unit 150 transmits the transmission control information in which the network address is set to “10.0.0.10” to the boundary router 60 b corresponding to the boundary router identification information “R1002”. This transmission control information is transmitted to the border router 60b via the communication control unit 110.

  When the border router 60b receives the transmission control information including the network address “10.0.0.10”, the border router 60b transmits the route information of the network address “10.0.0.10” to the network 70. Stop.

  In addition, the notification unit 150 transmits the transmission control information in which the network address is set to “10.0.0.20” to the border router 60a corresponding to the border router identification information “R1001”. This transmission control information is transmitted to the border router 60a via the communication control unit 110.

  When the border router 60a receives the transmission control information including the network address “10.0.0.20”, the border router 60a transmits the route information of the network address “10.0.0.20” to the network 70. Stop.

  When the transmission control information as described above is transmitted to the border routers 60a and 60b, the border router 60a transmits the route information including the network address “10.0.0.10” to the network 70. In addition, the border router 60 b transmits route information including the network address “10.0.0.20” to the network 70.

  Next, a processing procedure of the system according to the second embodiment will be described. FIG. 6 is a flowchart of the process procedure of the system according to the second embodiment. The flowchart shown in FIG. 6 is started when, for example, the border routers 60a and 60b receive the route information.

  As shown in FIG. 6, the border router 60a receives the route information (step S101a) and transmits the route information to the management apparatus 100 (step S102a). The border router 60b receives the route information (step S101b) and transmits the route information to the management apparatus 100 (step S102b).

  The management device 100 receives the route information from each border router (step S103), and updates the ASBR management table 130a (step S104). Based on the cost, the management apparatus 100 determines a border router that does not permit transmission of route information (step S105), and performs transmission control of route information based on the determination result (step S106). If the management apparatus 100 continues the process (step S107, Yes), the management apparatus 100 proceeds to step S103. If the management device 100 does not continue the processing (No at Step S107), the management device 100 ends the processing.

  The border router 60a transmits the route information to the network 70 when it does not receive the information prohibiting the transmission of the route information after a predetermined time has elapsed since the route information was transmitted to the management device 100 (step S108a). When the border router 60a continues processing (step S109a, Yes), the border router 60a proceeds to step S101a. On the other hand, when the border router 60a does not continue the process (No at Step S109a), the border router 60a ends the process.

  The border router 60b transmits the route information to the network 70 when it does not receive the information prohibiting the transmission of the route information after a predetermined time has elapsed since the route information was transmitted to the management device 100 (step S108b). If the border router 60b continues the process (step S109b, Yes), the border router 60b proceeds to step S101b. On the other hand, when the border router 60b does not continue the processing (step S109b, No), the border router 60b ends the processing.

  Next, effects of the management apparatus 100 according to the second embodiment will be described. Based on the path information received from the border routers 60a and 60b, the management apparatus 100 determines the border router that minimizes the cost when sending and receiving data to and from the network that is the destination of data transmission and reception. Then, based on the determination result, the management device 100 transmits transmission control information to a border router that does not permit transmission of route information. As a result, the border router to which transmission control information has not been transmitted transmits the route information, so that it is possible to prevent the same route information from looping through each network.

  In addition, the management apparatus 100 transmits the transmission control information to the boundary router that does not permit the transmission of the route information, and does not transmit the transmission control information to the boundary router that permits the transmission of the route information. For this reason, the amount of network traffic can be reduced.

  In addition, when the ASBR management table 130a is updated, the management apparatus 100 resets the priority flag and transmits the transmission control information to the border router that does not permit transmission of route information. For this reason, it is possible to determine an optimum border router that transmits route information in response to a change in cost in the network.

  Incidentally, each component of the management apparatus 100 shown in FIG. 4 is functionally conceptual, and does not necessarily need to be physically configured as illustrated. That is, the specific form of distribution and integration of the management apparatus 100 is not limited to the illustrated one, and all or a part of the management apparatus 100 is functionally or physically distributed in arbitrary units according to various loads and usage conditions. -Can be integrated and configured.

  For example, the router 71 or 72 is provided with the functions of the path information registration unit 120, the storage unit 130, the determination unit 140, and the notification unit 150 of the management device 100. The router 71 or 72 can manage the management device 100 in addition to the data transfer process. 100 processes may be executed.

  The management apparatus 100 can also be realized by mounting each function of the management apparatus 100 on an information processing apparatus such as a known personal computer, workstation, mobile phone, PHS terminal, mobile communication terminal, or PDA.

  FIG. 7 is a diagram illustrating a hardware configuration of a computer constituting the management apparatus according to the embodiment. As shown in FIG. 7, the computer 200 includes a CPU (Central Processing Unit) 201 that executes various arithmetic processes, an input device 202 that receives input of data from a user, and a monitor 203. The computer 200 includes a medium reading device 204 that reads a program and the like from a storage medium, and a network interface device 205 that exchanges data with other computers via a network. The computer 200 also includes a RAM (Random Access Memory) 206 that temporarily stores various information and a hard disk device 207. Each device 201 to 207 is connected to a bus 208.

  The hard disk device 207 stores a management program 207a corresponding to the path information registration unit 120, the determination unit 140, and the notification unit 150 illustrated in FIG. The hard disk device 207 stores various data 207b corresponding to the ASBR management table 130a of FIG.

  When the CPU 201 reads the management program 207a from the hard disk device 207 and expands it in the RAM 206, the management program 207a functions as the management process 206a. In addition, the CPU 201 stores various data 207 b stored in the hard disk device 207 in the RAM 206.

  Based on the path information received from each border router and the various data 206b stored in the RAM 206, the management process 206a determines a border router that permits transmission of path information, and transmits the determination result to the border router.

  Note that the management program 207 a is not necessarily stored in the hard disk device 207. For example, the management program 207a stored in a storage medium such as a CD-ROM may be read and executed by the computer 200. The management program 207a may be stored in a public line, the Internet, a LAN (Local Area Network), a WAN (Wide Area Network), or the like. In this case, the computer 200 may read out and execute the management program 207a therefrom.

  The following supplementary notes are further disclosed with respect to the embodiments including the above examples.

(Supplementary note 1) From a plurality of border routers connected between a plurality of networks having different routing protocols, router identification information for uniquely identifying the border router, and network identification for uniquely identifying a network to which data is transmitted and received A receiving unit that receives path information including information and a cost for transmitting and receiving data to and from the network;
A determination unit that compares a set of the network identification information and the cost of each path information, and determines a border router of the router identification information corresponding to the minimum cost among the costs corresponding to the same network identification information;
A management device comprising: a notification unit that notifies each border router of whether or not to permit transmission of the route information based on a determination result of the determination unit.

(Supplementary Note 2) The notification unit notifies information indicating that transmission of route information including the network identification information is not permitted to border routers other than the border router corresponding to the combination of the minimum cost and the network information. The management apparatus according to appendix 1, characterized by:

(Additional remark 3) It further has a memory | storage part which memorize | stores the route information which the said receiving part receives, The said receiving part updates the route information of the said memory | storage part, whenever the route information is received from the said border router, The said determination part The management device according to appendix 1 or 2, wherein a border router of router identification information corresponding to a set of minimum cost and network identification information is determined every time the route information of the storage unit is updated .

(Appendix 4)
From a plurality of border routers connected between a plurality of networks having different routing protocols, router identification information for uniquely identifying the border router, network identification information for uniquely identifying a network to which data is transmitted and received, and A receiving procedure for receiving route information including the cost of sending and receiving data to and from the network;
A determination procedure for comparing a set of the network identification information and the cost of each path information, and determining a border router of the router identification information corresponding to the minimum cost among the costs corresponding to the same network identification information;
And a notification procedure for notifying each border router of information on whether to permit transmission of the route information based on a determination result of the determination procedure.

(Supplementary Note 5) The notification procedure notifies the router other than the border router corresponding to the set of the minimum cost and the network information that the transmission of the route information including the network identification information is not permitted. The management program according to appendix 4, which is characterized.

(Appendix 6) The management device
From a plurality of border routers connected between a plurality of networks having different routing protocols, router identification information for uniquely identifying the border router, network identification information for uniquely identifying a network to which data is transmitted and received, and A receiving step for receiving route information including a cost for transmitting / receiving data to / from the network;
A determination step of comparing a pair of the network identification information and the cost of each path information, and determining a border router of the router identification information corresponding to the minimum cost among the costs corresponding to the same network identification information;
And a notification step of notifying each border router of information as to whether or not to permit transmission of the route information based on the determination result of the determination step.

(Supplementary note 7) The notification step notifies a router other than the border router corresponding to the set of the minimum cost and network information that the transmission of the route information including the network identification information is not permitted. The management method according to appendix 6, which is characterized.

(Supplementary note 8) A management system having a plurality of border routers and management devices connected between a plurality of networks having different routing protocols,
The border router
When route information including network identification information for identifying the network from the network and cost for transmitting / receiving data to / from the network is received, router identification information for uniquely identifying its own device is included in the route information. A route information notification unit for notifying the management device of the route information after storing,
The management device
Boundary router that receives route information from a plurality of border routers, compares a pair of the network identification information and the cost of each route information, and corresponds to the minimum cost among costs corresponding to the same network identification information A determination unit for determining
A communication system comprising: a notification unit that notifies each border router of whether or not to permit transmission of the route information based on a determination result of the determination unit.

50 Management Device 51 Receiving Unit 52 Judgment Unit 53 Notification Unit

Claims (5)

From a plurality of border routers connected between a plurality of networks having different routing protocols, router identification information for uniquely identifying the border router, network identification information for uniquely identifying a network to which data is transmitted and received, and A receiving unit that receives route information including the cost of sending and receiving data to and from the network;
A determination unit that compares a set of the network identification information and the cost of each path information, and determines a border router of the router identification information corresponding to the minimum cost among the costs corresponding to the same network identification information;
A management device comprising: a notification unit that notifies each border router of whether or not to permit transmission of the route information based on a determination result of the determination unit.   The notifying unit notifies information indicating that transmission of route information including the network identification information is not permitted to a border router other than the border router corresponding to the set of the minimum cost and the network information. The management apparatus according to claim 1.   The information processing apparatus further includes a storage unit that stores route information received by the receiving unit, and the receiving unit updates route information in the storage unit each time route information is received from the border router, and the determination unit includes the storage unit. 3. The management apparatus according to claim 1, wherein a border router of router identification information corresponding to a set of minimum cost and network identification information is determined each time the route information of each part is updated. On the computer,
From a plurality of border routers connected between a plurality of networks having different routing protocols, router identification information for uniquely identifying the border router, network identification information for uniquely identifying a network to which data is transmitted and received, and A receiving procedure for receiving route information including the cost of sending and receiving data to and from the network;
A determination procedure for comparing a set of the network identification information and the cost of each path information, and determining a border router of the router identification information corresponding to the minimum cost among the costs corresponding to the same network identification information;
And a notification procedure for notifying each border router of information on whether to permit transmission of the route information based on a determination result of the determination procedure. A management system having a plurality of border routers and a management device connected between a plurality of networks having different routing protocols,
The border router
When route information including network identification information for identifying the network from the network and cost for transmitting / receiving data to / from the network is received, router identification information for uniquely identifying its own device is included in the route information. A route information notification unit for notifying the management device of the route information after storing,
The management device
Boundary router that receives route information from a plurality of border routers, compares a pair of the network identification information and the cost of each route information, and corresponds to the minimum cost among costs corresponding to the same network identification information A determination unit for determining
A communication system comprising: a notification unit that notifies each border router of whether or not to permit transmission of the route information based on a determination result of the determination unit.

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